Evaluation of in vitro antioxidant and apoptotic activities of Cyperus rotundus

Document heading _doi:

Evaluation of in vitro antioxidant and apoptotic activities of Cyperus

rotundus

Kilani-Jaziri Soumaya

_{, Ghedira Zied}

_{, Nasr Nouha}

_{, Krifa Mounira}

_{, Ghedira Kamel}

_{, Franca}

Dijoux Marie Genvi

侉ve

_{, Ghedira Chekir Leila}

1_{Unit佴 de Substances Naturelles Bioactives et Biotechnologies UR12ES12, Universit佴 de Monastir, Facult佴 de Pharmacie de Monastir}

2_{Laboratoire de Biologie Mol佴culaire et Cellulaire, Facult佴 de M佴decine Dentaire de Monastir, Universit佴 de Monastir, Rue Avicenne, 5019 Monastir,}

Tunisie

3_{Laboratoire de Botanique, Pharmacognosie et Phytoth佴rapie, UMR CNRS 5557 Ecologie Microbienne; Institut des Sciences Pharmaceutiques et}

Biologiques-Facult佴 de Pharmacie Universit佴 Claude Bernard, B昞timent N佴tien-8 Avenue Rockefeller-69373 Lyon cedex 08, France Contents lists available at ScienceDirect

Asian Pacific Journal of Tropical Medicine

journal homepage:www.elsevier.com/locate/apjtm

ARTICLE INFO ABSTRACT

Article history: Received 10 July 2013

Received in revised form 15 August 2013 Accepted 15 September 2013 Available online 20 February 2014 Keywords:

Polyphenols

Orientin

Xanthine/Xanthine oxidase assay

Lipid peroxidation assay

Deoxyribose assay

DNA fragmentation

*Corresponding authors: Leila G. Chekir, Faculty of Dental Medicine, Rue Avicenne, 5019 Monastir, Tunisia.

Fax: 00216 73 461 150 E-mail: leila.chekir@laposte.net

1. Introduction

Overproduction of reactive oxygen species is considered a major cause of molecular injury and is implicated in the pathogenesis of several human diseases and age-related degenerative processes[1]. _Interest in the natural sources of

antioxidant molecules in the food, beverage, and cosmetic

industries has resulted in a large body of research in the recent years characterizing the mechanisms of action of well known lipid and water-soluble antioxidants such as tocopherols and ascorbic acid, respectively, as well as the antioxidants isolated from herbs, spices, oilseeds, green and black tea, citrus fruits, grapes, and alcoholic beverages[2].

Among these, the natural polyphenolic compounds, especially flavonoids, have been largely studied for their strong antioxidant capacity[3], and they have been

demonstrated to possess a therapeutic potential in some human disorders, including cancer, atherosclerosis, and liver diseases[4]. _Supporting this, the antioxidant and

Objective:To evaluate in vitro antioxidant and apoptotic activities of Cyperus rotundus (C.

rotundus). Methods:The phytochemical study and the antioxidant activities of both methanol and aqueous extracts from C. rotundus aerial part were determined. In addition, these extracts were also investigated for their cytotoxic and apoptotic activities. The major compound of the methanol extract was isolated. Both methanol and aqueous extracts (300, 150, and 50 _毺g/mL) were

evaluated for their antioxidant activity by the xanthine/xanthine oxidase assay system. However,

16, 8, and 4 mg/mL of each extract were tested to investigate their OH. formation scavenging potential. Aqueous extract (800, 400, and 200 _毺g/mL) and methanol extract (350, 175, and 88 _毺g/mL)

were tested against lipid peroxidation, induced by 75 _毺MH2O2. The cytotoxicity (by MTT assay)

and cell DNA fragmentation of both extracts were evaluated towards K562 and L1210 cell lines.

The major compound was obtained from the butanol fraction of methanol extract and its structure was determined by RMN spectroscopic analysis. Results:The methanol and aqueous extracts showed respectively, 88% and 19% inhibition of xanthine oxidase activity. Yet, the same extracts inhibited lipid peroxidation by 61.5% and 42.0%, respectively. Both extracts inhibited OH. formation by 27.1% and 25.3%, respectively. Only methanol extract induced DNA degradation.

Orientin was determined as the major compound isolated from the butanol fraction of methanol extract. Conclusions:It appears that C. rotundus extracts exhibit a potential use as a natural antioxidant and an apoptosis inducer.

chemoprotective properties of individual food flavonoids or polyphenolic extracts have been widely reported in cultured cells[5], animal models[6] and humans[7].

Cyperus rotundus (C. rotundus) Linn, a sedge of the

Cyperaceae family, is widely scattered in the Mediterranean basin areas. This plant, which grows naturally in tropical, sub-tropical and temperate regions, is widespread in the north-east, Center and south Tunisia[8]. C. rotundus is a

traditional medicinal plant appearing among Indian, Chinese and Japanese natural drugs used against spasms, stomach disorders, and inflammatory bowel diseases[9]. _Although

it has already been demonstrated that aerial parts of C. rotundus contain phenolic compounds, little is known about their antioxidant and antigenotoxic potentials[10,11]. _We firstly

investigated the effects of aqueous and methanol extracts from the aerial parts of C. rotundus, on the genotoxicity induced by both Aflatoxin B1 (AFB1) and sodium azide, in a

bacterial assay system, ie. the Ames test. The two extracts also exhibited an important free radical scavenging activity towards the 1,1-diphenyl-2-picrylhydrazyl (DPPH.) free

radical[10]. _Previous phytochemical studies on C. rotundus

revealed the presence of alkaloids, flavonoids, tannins, starch, glycosides and furochromones, and many novel sesquiterpenoids[12-14].

Accordingly, in the present study, the antioxidant properties of the aerial part extracts were evaluated through biochemical assays ie.; the xanthine/xanthine oxidase enzymatic assay system, deoxyribose assay and the inhibition of lipid peroxidation induced by H2O2 in the Human chronic myelogenous leukemia cell line K562, through the formation of thiobarbituric acid-reactive substances. Furthermore, the effects of C. rotundus on cell proliferation and apoptosis induction in murine and human leukemia cells were also examined. Besides, the main phenolic (orientin) compound in the methanol extract was

isolated by chromatographic methods and was determined by spectroscopic data analysis and by a comparison with the literature.

2. Materials and methods 2.1. Plant material

C. rotundus aerial parts were collected in the region of

Monastir in the Center of Tunisia in October 2007. The botanical identification was carried out by Pr. M. Chaieb

(Department of Botany, Faculty of Sciences, University of Sfax, Tunisia), according to the flora of Tunisia[8]. _A

voucher specimen (Cp.10-07) was kept in the laboratory of Pharmacognosy, Faculty of Pharmacy of Monastir, for future reference.

2.2. Preparation of plant extracts

The fresh aerial parts of C. rotundus, were dried at room temperature and reduced to coarse powder. In the present

study, two extracts were investigated. The powdered leaves were extracted by boiling water for 15 to 20 min. The crude extract obtained was filtered and lyophilized (aqueous

extract); Methanol extract was obtained by Soxhlet extraction (6 h). This extract was concentrated to dryness and the

residue was kept at 4 曟.

2.3. Quantitative analysis of extracts

2.3.1. Determination of total polyphenol and flavonoid content

The polyphenol content of C. rotundus was quantified by the Folin-Ciocalteau reagent[15].

The polyphenol content was expressed according to the following formula:

% polyphenols = [(DOextract 暳0.2/DOGallic acid)/Extract concentration] 暳100

A known volume of each extract was placed in a 10 mL

volumetric flask to estimate the flavonoid content according to the method of Zhishen et al[16].

The flavonoid content was expressed according to the following formula:

% flavonoids = [(DOextract 暳0.05/DOQuercetin)/Extract concentration] 暳100.

2.3.2. Determination of tannin content

The method described by Ch昞abane et al[17] was used for

the determination of tannin content of the samples.

The tannin content (tannic acid equivalents) was calculated

in triplicate, using the following formula:

% tannins =[(DOextract/毰暳 1)/Extract concentration] 暳100,

W_{here 毰; molar extinction coefficient} (l g-1cm-1) of tannic

acid (= 3.27 l g-1cm-1) and l = 1 cm.

2.4. Extraction and isolation of orientin

The residue of the methanol extract (10.6 g) was suspended

in warm water and incubated overnight at 4 曟. The following day, the solution was filtered and successively portioned between water and chloroforme (v/v). The aqueous phase is

then recuperated and treated with 1-butanol saturated in water (v/v). Each liquid-liquid extraction was carried out three times. The obtained sub-extracts were concentrated by evaporation under vacuum to dryness.

The butanol soluble fraction (0.9 g) was purified by passage

through C-18 gel disposable extraction column eluted with a gradient H2O: MeOH(90:10 to 0:100) increasing MeOH contents and 15 sub-fractions were collected. Sub-fraction 9 was chromatographed over Sephadex LH-20 eluted with

MeOH: H2O(90:10) to afford 3 mg of orientin. This compound was identified by comparaison of its NMR data with the literature[18]. _Nuclear magnetic resonance spectra were

obtained using a Bruker襆_Avance spectrometer, operating at 300 MHz for 1_{H. Dimethyl sulfoxide (DMSO-d}

6) was used as a solvent.

2.5. Evaluation of xanthine oxidase inhibition effect

The inhibition of xanthine oxidase (XO) was measured

according to the decrease in uric acid absorbance at 290 nm as proposed by Limem et al[19]. _The tested concentration was

50, 150, and 300 _毺g/mL, for each extract.

2.6. Hydroxyl radical assay

The hydroxyl radical scavenging activity was determined according to the method of Halliwell et al[20]. _The hydroxyl

radical scavenging activity of the extracts was measured by the competition between deoxyribose and the extracts for the hydroxyl radicals generated from the Fe3+_{/ascorbate/EDTA/} H2O2 system (non site-specific assay) or Fe3+/ascorbate/

H2O2 (site-specific assay). The hydroxyl radical scavenging activity was calculated using the following formula: Hydroxyl radical scavenging activity (%) = [(A0 - A1/A0) 暳100], where

A0 is the absorbance of the control (without extract), and A1 is the absorbance in the presence of extract or the standard sample.

2.7. Cytotoxicity studies in vitro 2.7.1. Culture of cells

K562 (human chronic myelogenous leukemia) and L1210 (murine leukemia) cell lines were obtained from American

Type Culture Collection (Rockville, MD). The cells were cultivated in RPMI-1640 medium supplemented with 10% v/

v fetal calf serum, 1% gentamycin and 2 mM L-glutamine

as a complete growth medium. The cells were incubated at 37 曟 in an incubator with 5%CO2 in humidified atmosphere.

2.7.2. Assay for cytotoxic activity

The cytotoxicity of C. rotundus extracts against the two leukaemia cell lines was estimated by the MTT assay, based on the cleavage of the tetrazolium salt by mitochondrial dehydrogenases in viable cells. The resulting blue formazan product can be measured spectrophotometrically. The cytotoxic effects of the extracts were estimated in terms of growth inhibition percentage and expressed as IC50[21].

2.8. Lipid peroxidation inhibitory activity

Lipid peroxidation inhibition activity was monitored by the measurement of malondialdehyde (MDA) according to

the method of Ben Ammar et al[22]. _The cells were exposed

to various concentrations of each extract in the incubation during 2 h, followed by 75 _毺MH2O2 treatment for 2 h. The inhibitory activity towards lipid peroxidation was expressed as IC50 (concentration of extract giving 50% inhibition of

MDA-TBA complex formation) compared to control solution,

without the tested extract.

2.9. Electrophoretic analysis of DNA fragmentation

DNA fragmentation was analysed by agarose gel

electrophoresis as described by Wang et al[23], with slight

modifications. L1210 and K562 cells (1.5暳106 cells/mL)

were exposed to the extract for 24 and 48 h and harvested by centrifugation. The cells were then treated to extract chromosomal DNA which was transferred to a 1.5% agarose

gel. The gel was visualized under UV light after staining with ethidium bromide (1 毺g/mL).

2.10. Statistical analysis

Data were collected and expressed as the mean暲standard deviation of three independent experiments and IC50 values, from the in vitro data, were calculated by regression analysis. Statistical significance was determined using the

Student’s t-test. P<0.05 was considered as indicative of significance as compared to the control group.

3. Results

3.1. Total phenolics contents

The phytochemical study of C. rotundus extracts showed the presence of various quantities of total polyphenolic, flavonoids compounds and tannins. In this work, the total polyphenol content of the extracts was expressed as gallic acid equivalents[24] following confirmation of linearity of the

response of the assay using the extract. The total flavonoid content of the C. rotundus extracts was determined by the method of Zhishen et al[16].

The phytochemical study of both methanol and aqueous extracts revealed the presence of polyphenols [respectively,

(290.0暲14.5) and (200.0暲3.0) 毺g equivalent of gallic acid/

mg of each extract], and falvonoids [respectively, (330.0暲

11.0) and (260.0暲2.5) 毺g equivalent of quercetin/mg of each

extract). Yet, tannins were weaker with respectively (68.7暲

2.5) and (59.6暲8.5) 毺g/100 mg of the extract. The percent yield of the aqueous extract was 13.7% and the methanol

extract was 13.2%. On the other hand, we were interested in fractionating the methanol extract not the aqueous extract in this work, because the methanol extract is the most active extract tested in the different in vitro methods to evaluate the antioxidant and apoptotic activities compared to the aqueous extract.

3.2. Identification of orientin

The structural identification of orientin was established using spectroscopic analysis, especially, NMR spectra and a direct comparison with the published data. This predominant compound (Figure 1) was found to belong to

the secondary metabolite class of flavonoids and it might influence the antioxidant and apoptotic activities of the methanol extract. This compound is one among other flavonoids, not yet identified in this extract, and which we discussed its potential role in the biological activities of the original extract.

Figure 1. Orientin.

3.3. Evaluation of xanthine oxidase activity

We evaluated the influence of the aqueous and methanol extracts isolated from C. rotundus aerial parts on the xanthine oxidase activity, in an enzymatic oxidation system of xanthine to uric acid and superoxide anion as final products. This system seems to be more related to the physiological conditions[25]. _In _Figure 2, we reported that

increasing concentrations of both aqueous and methanol extracts lead to a progressively decreased formation of uric acid and therefore to the superoxide anion. It seems that methanol extract is more efficient to inhibit xanthine oxidase when compared to the aqueous extract with respectively 88%

and 19% at the same concentration of 300 毺g/mL.

100 90 80 70 60 50 40 30 20 10 0

Inhibition of Uric acid production 50 毺g/mL 150 毺g/mL 300 毺g/mL

Doses (毺g/mL)

Aqueous extract Methanol extract *

* *

Figure 2. Inhibition of uric acid production by xanthine oxidase reaction in the presence of different concentrations of aqueous and methanol extracts from C. rotundus.

*: P< 0.05 as compared with the control group.

3.4. Hydroxyl radical scavenging activity

_{In the present study, we examined the inhibitory action} of aqueous and methanol extracts on deoxyribose assay which gives an indication of hydroxyl radical scavenging action and iron chelating activity[26]. _Both aqueous and

methanol extracts of C. rotundus displayed hydroxyl radical scavenging activity. As shown in Figure 3, these extracts exhibited dose-dependent inhibitory effects on hydroxyl radical formation. The maximal inhibitory percentages were 25.3% and 27.1% in the presence of the aqueous and the

methanol extracts (16 mg/mL), respectively. The methanol extract exhibited higher metal ion chelating activity than the

aqueous extract with an inhibitory percentage of 62.5% at 16

mg/mL(Figure 4). 30 25 20 15 10 5 0

Hydroxyl radical scavenging

4 8 16 Doses (mg/mL)

Aqueous extract Methanol extract

* * *

Figure 3. Hydroxyl radical scavenging effect of C. rotundus extracts. *: P< 0.05 as compared with the control group.

70 60 50 40 30 20 10 0 Metal chelation (% ) _{* *} * 4 8 16 Aqueous extract Methanol extract

Doses (mg/mL)

Figure 4.Metal ion chelating activity of C. rotundus extracts. *: P<0.05 as compared with the control group.

3.5. Effect of different extracts on the proliferation of L1210 and K562 leukemia cells

It is well known that the different cell lines might exhibit different sensitivities to a given compound, the use of more than one cell line is, therefore, considered necessary in the detection of the antiproliferative substances. Thus, the relationship between the concentration of the extracts and their cytotoxic effect on L1210 and K562 cells were investigated by MTT assay. The results of this experiment demonstrated that the methanol extract showed a higher cytotoxic effect on K562 cells [IC50 = (175.0暲1.2) 毺g/mL] compared to that observed on L1210 cells [IC50 = (400.0暲1.3) 毺g/mL]. No significant cytotoxic activity was shown towards

L1210 and K562 cells after treatment with up to 800 _毺g/ mL aqueous extract. These results show that the methanol active extract from C. rotundus inhibited the proliferation of both murine and human leukemia cells in a concentration-dependent manner.

3.6. Anti-lipid peroxidation activity

The inhibitory effects of the different concentrations of C. rotundus extracts on MDA production, induced by H2O2 in K562 cell line, are shown in Table 1. The inhibition of

MDA formation increases with increasing concentrations of each of the tested extracts. The anti-lipid peroxidation activity was obtained at the concentration range of 88 to 350 _毺g/mL of methanol extract and of 200 to 800 _毺g/mL of

aqueous extract, and the inhibition rates were in the range of respectively, 57.3% to 61.5% and 24.7% to 42.0%. The methanol extract showed more significant protection effect than the aqueous extract at the same concentrations, against lipid peroxidation. The 50%MDA inhibitory concentration

(IC50) value of the methanol extract was determined by the thiobarbituric acid test was 40 _毺g/mL, IC50 of while aqueous extract was >800 _毺g/mL.

Table 1

Protective effect of C. rotundus extracts against lipid peroxidation induced by H2O2(75 毺M) in K562 cells.

Extract Concentration (_毺g/mL) % inhibitiona

Aqueous extract 200 24.7暲1.0 400 29.0暲0.9* 800 42.0暲1.0* Methanol extract 88 57.3暲1.0* 175 60.0暲0.8* 350 61.5暲0.6*

a_{Results are means暲standard deviation of duplicate analysis of} three replications. *: P<0.05 as compared with the control group.

3.7. Induction of apoptotic DNA fragmentation by extracts

The examination of electrophoretic profiles revealed a DNA

ladder formation characteristic of apoptosis (Figure 5). L1210

cells exposed to 400 and 800 _毺g/mL of the methanol extract during 48 h, showed a clearly fragmented DNA, whereas the control cells did not provide this specific ladder DNA profile.

However, the cells treated with the aqueous extract exhibited no ladder DNA profile with L1210 as well as with K562 cells.

The higher sensitivity of L1210 cells to the methanol extract-mediated inhibition of proliferation compared to aqueous extract, suggests a selective influence of methanol extract on L1210 cells. We deduce that the methanol extract from C. rotundus induce apoptosis of L1210 cells.

A B C D E F G

48 h 24 h

Figure 5.Agarose gel electrophoresis of DNA extracted from L1210

cells treated with methanol extract.

(A)800 _毺g/mL, (B)400 _毺g/mL and (C)200 _毺g/mL for 48 h, (D)800

毺g/mL, (E)400 _毺g/mL and (F)200 _毺g/mL for 24 h, (G) control (non

treated cells).

3.8. Correlations of antioxidant activities in different in vitro model systems and cytotoxic effect of extracts with their total phenolic content

Polyphenols have been reported to be responsible for the antioxidant and apoptotic activities of the extracts[27].

We undertook to evaluate the correlation extent between the antioxidant activities and the phenolic content of the tested extracts by using a linear regression analysis. The correlation of the total phenolic content against the different activities was satisfactory (r>0.7). Our results proved that the phenolic content and the antioxidant activity induced by the aqueous extract correlate very well when testing its effect against uric acid and O2. formations using X/XO assay as well as its ability to chelate iron ions in deoxyribose assay (r=0.956 and r=0.954, respectively). We also detected a good correlation between the inhibition percentage of lipid peroxidation, hydroxyl radical scavenging percentage, and its chemical contents (r=0.872 and r=0.773, respectively). However, a higher correlation (r=0.997) was detected between

the mean values of the total phenolic contents of methanol extract and its hydroxyl radical scavenging effect. This same extract revealed a significant inhibitory effect against lipid peroxidation and xanthine oxidase activity. These inhibitory effects are highly correlated to the total phenolic content of the extract respectively, r=0.976 and r=0.880.

Nevertheless, a less significant correlation was revealed between the hydroxyl radical scavenging effects of both aqueous extract and methanol extract, and their phenolic contents (respectively r=0.773 and r=0.734). These results could be partially explained by the fact that, the kinds of phenolic content should influence the biological activity of a given extract[28]. _Besides, the cytotoxic effect towards _K562

and L1210 cells, of both aqueous and methanol extracts, was strongly correlated with the total phenolic contents with respectively, r=0.982 and r=0.998 in the presence of aqueous extract and r=0.999 and r=0.897 in the presence of methanol extract.

4. Discussion

Increasing attention is given to the study of natural products, which may counteract the detrimental effects of environmental toxic compounds and prevent multiple human diseases such as neurodegenerative diseases, ageing, rheumatoid arthritis, metabolic diseases such as atherosclerosis, diabetes, hypertension, cancer, etc.. In this line, different medicinal plants have been re-evaluated and recognized as valuable sources of nutraceuticals[29].

Recently, several dietary supplements containing vitamins, polyphenols, or flavones also play a significant role in this matter. Phenolic compounds are very important plant constituents because they exhibit an antioxidant activity by inactivating lipid free radicals or preventing decomposition

of hydroperoxides into free radicals[30].

This study is designed to evaluate the antioxidant and apoptotic activities of C. rotundus extracts employing a variety of in vitro methods. The antioxidant activity was tested using different in vitro tests ie.; the xanthine/xanthine oxidase enzymatic assay system and the deoxyribose assay.

The xanthine/xanthine oxidase assay demonstrated that the methanol extract is an effective inhibitor of xanthine oxidase. In fact, the preliminary chemical study showed that flavonoid, tannin and polyphenol contents in the methanol extract are higher than those detected in the aqueous extract[10]. _Thus, we can ascribe the higher antioxidant

activity of the methanol extract compared to that of the aqueous extract to its high flavonoids, a group of natural products exhibiting many biological and pharmacological activities. The inhibition of several enzymes by flavonoids has been demonstrated[31]. _Besides, it has been reported that

flavonoids inhibit xanthine oxidase and have superoxide scavenging activities[17]. _As orientin is the predominant

compound in methanol extract, we hypothesized that it might influence the antioxidant activity of this extract. In fact, orientin is reported by Makio et al[32] to have

anti-DPPH activity and superoxide radical scavenging effect.

However, we cannot exclude other minor phenolic[11,33]

or non-phenolic compounds that could participate in the antioxidant activity of this extract. The antioxidant activity is generally the result of the combined activities of a wide range of compounds, including phenolics (eg. orientin),

peptides, organic acids and other components[34].

Likewise, the antioxidant capacity of C. rotundus extracts was evaluated by deoxyribose assay which gives an indication of hydroxyl radical scavenging action and iron chelating activity. The hydroxyl radical is an extremely reactive free radical formed in biological systems and is implicated as a highly damaging species in free radical pathology, capable of damaging the biomolecules of the living cells. In addition, this radical species has the capacity to cause DNA strand breakage, which contributes to carcinogenesis, mutagenesis and cytotoxicity[35]. _On

the other hand, iron is known to generate free radicals through the Fenton and Haber-Weiss reaction. The metal ion chelating activity of an antioxidant component prevents oxyradical generation and the resulting oxidative damages.

Metal ion chelating capacity also plays a significant role in the antioxidant mechanism since it reduces the concentration of the catalysing transition metal in lipid peroxidation[36]. _In fact, the methanolic extract exhibited

higher metal ion chelating activity than aqueous extract and displayed hydroxyl radical scavenging activity.

We conclude that, the antioxidant activity of the tested extracts evaluated by the different methods may be correlated with their phenolic contents. Plant phenolic compounds constitute one of the major groups of compounds acting as primary antioxidants and free radical terminators by donating hydrogen from the phenolic hydroxyl

groups[17,37]. _Flavones _C-glycosides are of particular interest

because of their limited occurrence in plants and their important therapeutic properties, including the prevention of cardiovascular disorders related to oxidative stress.

In tissue cultures of Passiflora quadrangularis, several

C-glycosylated flavones such as isoorientin, orientin, vitexin and isovitexin were induced in varied amounts, and their antioxidant activity was determined by DPPH assay[38,39].

However, orientin was predominant in C. rotundus methanol extract, and might influence the antioxidant activity in the different tested in vitro model systems.

In order to screen the cytotoxic effects of all extracts, we performed a preliminary study on the cytotoxicity of the extracts in K562 and L1210 cell lines exposed to various extract concentrations. Our results indicate that methanol extract was the most active extract against both of the two cell-lines which differ by their origin and morphology. It is suggested that polyphenolic compounds have inhibitory effects on mutagenesis and carcinogenesis in humans[10,37].

Some studies have shown that flavonoids are able to influence a variety of cell function by modulating cell signalling, altering proliferation and inducing cytotoxicity in cancer cell lines[40]. _Moreover, flavonoids showed cytotoxic

effects on various human cell lines, such as leukaemia cells and ovarian cancer cells[41]. _Orientin is one of the main

flavonoids identified in the methanol extract of C. rotundus.

This compound is described as reducing by half the number of cancer-associated changes in the cells of human blood exposed to radiation[42]. _However, minor components could

also contribute to the cytotoxic activity of this extracts. It is also possible that the components act synergistically to allow the extract to be active.

On the other hand, the low cytotoxicity exhibited by the aqueous extract indicates that the compounds present in this extract are weakly cytotoxic. The difference in cytotoxicity of both extracts may be attributed to the differences in the ratio of compounds involved in the cytotoxicity of each extract.

However, we cannot exclude the role of other compounds apart from polyphenols, tannins or flavonoids in this cytotoxic effect. In fact, as reactive oxygen radicals play an important role in carcinogenesis[43], it is possible to suggest

that the presence of antioxidants in the C. rotundus extracts may play some roles in reducing cancerous cell number. Lipid peroxidation has been broadly defined as the oxidative deterioration of polyunsaturated lipids. MDA

is usually taken as a marker of lipid peroxidation and oxidative stress[44]. _The data obtained showed that the

inhibition percentage of MDA formation induced by H2O2 in the leukemia cell line K562 increases with increasing concentrations of each of the tested extracts. In our previous study, we showed that the tested extracts contained higher flavonoids and tannins in the methanol extract than in the aqueous extract. These findings suggest that there can be a correlation between the antioxidant activity and phenolic content of each extract. On the other hand, the aqueous

extract showed the lowest antioxidant activity compared to the methanol extract. This may be due to variation in the quality and quantity of the different compounds present in the aqueous extracts.

In fact, flavonoids have been shown to exhibit antioxidative, antiviral, antimicrobial, antiplatelet and antitoxic activities[45]. _The biological activities of these polyphenols

in the different systems are believed to be due to their redox properties, which can play an important role in absorbing and neutralizing free radicals, quenching singlet and triplet oxygens, or decomposing peroxides[46,47]. _Markham et al[48]

reported that 3',4'-dihydroxyflavonoids (eg. orientin, and

quercetin glycoside) are capable of free radical scavenging

and this might be a very important response to UV-damage in plants.

To investigate whether the anti-proliferative effect of C. rotundus extracts is due to induction of apoptosis, an electrophoretic analysis of DNA fragmentation was used.

Methanol extract exhibited a ladder DNA profile only in

L1210 cells. The apoptotic effect of C. rotundus on leukemia

L1210 cells reflects its potential therapeutic value in cancer treatment and we hypothesised that the regulation of apoptotic genes may be controlled by their phenolic content. As far as C. rotundus extracts tested in the present study were in crude form and probably contained many compounds which may well act synergistically, it is not possible to say which compounds are responsible for the observed effects. However, our data suggest that the biological effects exhibited by this plant, under these experimental conditions, could be related to an overall effect of the tannins and flavonoids in these extracts. However, as for asorientin, one of the major compound detected in the methanol extract, it is reported to have significant protection to the human lymphocytes against the clastogenic effect of radiation, radiation lethality and chromosomal aberrations in vivo[49]. _We believe that orientin largely contribute to the

apoptotic effect of the methanol extract on L1210 cells. The correlation coefficients exhibited a high relationship between total phenolic content in the methanol extract and its cytotoxic effect on one hand and its antioxidant activity on the other hand compared to the aqueous extract.

The present study suggests that the extracts of C. rotundus plant are potential sources of natural antioxidants and cytotoxicant. However, the in vivo safety of these extracts needs to be thoroughly investigated in animal experiments prior to its possible application as an antioxidant ingredient, either in animal feeds or in human healthy foods. Further studies are needed on the isolation and characterization of individual compounds to elucidate their different antioxidant mechanisms and the existence of possible synergism, if any, among the compounds.

Conflict of interest statement

We declare that we have no conflict of interest.

Acknowledgments

The authors are grateful to the “Minist侉re Fran觭ais des

Affaires Etrang侉res” (Action Int佴gr佴e de Coop佴ration

Inter universitaire Franco-Tunisienne, PHC UTIQUE 07

G0836 PAR), to the Ministry of Higher Education, Scientific

Research and Technology in Tunisia for the financial assistance of this study and also thank Mr. Samir Boukattaya

(Pr. of English at the Faculty of Dental Medicine, Tunisia) for English editing.

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